1-Phenyl-3-(1-phenyl-1-(pyridin-2-yl)ethyl)isoquinoline (H2MeL) has been prepared by Pd(N-XantPhos)-catalyzed "deprotonative cross-coupling processes" to synthesize new phosphorescent red iridium(III) emitters (601-732 nm), including the carbonyl derivative Ir(κ4-cis-C,C'-cis-N,N'-MeL)Cl(CO) and the acetylacetonate compound Ir(κ4-cis-C,C'-cis-N,N'-MeL)(acac). The tetradentate 6e-donor ligand (6tt') of these complexes is formed by two different bidentate units, namely, an orthometalated 2-phenylisoquinoline and an orthometalated 2-benzylpyridine. The link between the bidentate units reduces the number of possible stereoisomers of the structures [6tt' + 3b] (3b = bidentate 3e-donor ligand), with respect to a [3b + 3b' + 3b″] emitter containing three free bidentate units, and it permits a noticeable stereocontrol. Thus, the isomers fac-Ir(κ4-cis-C,C'-cis-N,N'-MeL){κ2-C,N-(C6H4-py)}, mer-Ir(κ4-cis-C,C'-cis-N,N'-MeL){κ2-C,N-(C6H3R-py)}, and mer-Ir(κ4-trans-C,C'-cis-N,N'-MeL){κ2-C,N-(C6HR-py)} (R = H, Me) have also been selectively obtained. The new emitters display short lifetimes (0.7-4.6 μs) and quantum yields in a doped poly(methyl methacrylate) film at 5 wt % and 2-methyltetrahydrofuran at room temperature between 0.08 and 0.58. The acetylacetonate complex Ir(κ4-cis-C,C'-cis-N,N'-MeL)(acac) has been used as a dopant for a red PhOLED device with an electroluminescence λmax of 672 nm and an external quantum efficiency of 3.4% at 10 mA/cm2.
1-Phenyl-3-(1-phenyl-1-(pyridin-2-yl)ethyl)isoquinoline (H2MeL) has been prepared by Pd(N-XantPhos)-catalyzed "deprotonative cross-coupling processes" to synthesize new phosphorescent red iridium(III) emitters (601-732 nm), including the carbonyl derivative Ir(κ4-cis-C,C'-cis-N,N'-MeL)Cl(CO) and the acetylacetonate compound Ir(κ4-cis-C,C'-cis-N,N'-MeL)(acac). The tetradentate 6e-donor ligand (6tt') of these complexes is formed by two different bidentate units, namely, an orthometalated 2-phenylisoquinoline and an orthometalated 2-benzylpyridine. The link between the bidentate units reduces the number of possible stereoisomers of the structures [6tt' + 3b] (3b = bidentate 3e-donor ligand), with respect to a [3b + 3b' + 3b″] emitter containing three free bidentate units, and it permits a noticeable stereocontrol. Thus, the isomers fac-Ir(κ4-cis-C,C'-cis-N,N'-MeL){κ2-C,N-(C6H4-py)}, mer-Ir(κ4-cis-C,C'-cis-N,N'-MeL){κ2-C,N-(C6H3R-py)}, and mer-Ir(κ4-trans-C,C'-cis-N,N'-MeL){κ2-C,N-(C6HR-py)} (R = H, Me) have also been selectively obtained. The new emitters display short lifetimes (0.7-4.6 μs) and quantum yields in a doped poly(methyl methacrylate) film at 5 wt % and 2-methyltetrahydrofuran at room temperature between 0.08 and 0.58. The acetylacetonate complex Ir(κ4-cis-C,C'-cis-N,N'-MeL)(acac) has been used as a dopant for a red PhOLED device with an electroluminescence λmax of 672 nm and an external quantum efficiency of 3.4% at 10 mA/cm2.
Phosphorescent
iridium(III) emitters currently receive a great
deal of attention due to their ability to reach internal quantum efficiencies
close to unity in their organic light-emitting diode (OLED) devices.[1] Because their emissions are ligand-dependent,
there is growing interest in heteroleptic complexes, particularly
in those bearing three different ligands. The reason for this is that
the emissive properties could be fine-tuned by an appropriate building
of the metal coordination sphere by means of an adequate selection
of the ligands; that is, it should be possible to design emitters
according to the requirements of a given application.[1,2]The building of iridium(III) complexes of type [3b + 3b′
+ 3b″] with three different 3e-donor bidentate ligands is challenging.
The preparation methods involving one-pot procedures give statistical
mixtures of ligand distribution products, where the maximum yield
of each one can become about 30%, before the necessary column chromatography
separation.[3] The synthesis through the
sequential coordination of the different ligands is a tedious multistep
procedure,[4] which has some success if the
three ligands are quite different. An additional problem is the existence
of structural isomers, which display their own photophysical properties.[5] An interesting approach to solve this dare is
to bind two ligands, 3b and 3b′, to form a heteroleptic 6e-donor
tetradentate ligand, 6tt′, with two different bidentate moieties.
In this way, the ligand distribution possibilities in the resulting pseudo-tris(heteroleptic) [6tt′ + 3b″] compounds
are reduced, which allows an increase of the reaction yield and facilitates
the chromatographic separation. In addition, a better structural control
should be reached as a result of the increase of the rigidity of the
system, which provides a decrease in the number of feasible stereoisomers.Tetradentate ligands are less common than monodentate, bidentate,
and tridentate. Macrocyclic and rigid acyclic dispositions providing
a planar skeleton are the most frequently used.[6] Iridium(III) emitters bearing nonplanar tetradentate ligands
are very scarce,[7] and particularly rare
are those formed by two different bidentate moieties. As far as we
know, only three ligands of this class have been previously used to
prepare iridium(III) emitters (Chart ). The 2,2′-(1-(6-(3-trifluoromethyl-1H-pyrazol-5-yl)pyridin-2-yl)ethane-1,1-diyl)dipyridine molecules
afford monoanionic N,N′,N″,N″-tetradentate ligands
(7tt′), which stabilize sky-blue [7tt′ + 2b] emitters A,[8] whereas exchanging one of the
peripheral pyridine for a phenyl group leads to 2-(3-trifluoromethyl-1H-pyrazol-5-yl)-6-(1-phenyl-1-(pyridyn-2-yl)ethyl)pyridine,
which forms a dianionic N,N′,C,N″-tetradentate ligand 6tt′.
This anion uses the free nitrogen atom of the pyrazolate group to
generate the green binuclear emitters B.[9] We have recently shown that the ortho-CH
bond activation of both phenyl groups of 2-phenyl-6-(1-phenyl-1-(pyridin-2-yl)ethyl)pyridine
gives a dianionic C,N,C′,N′-tetradentate 6tt′ ligand,
which allows the access to blue-green and green iridium(III) emitters, C and D, of classes [6tt′ + 1m + 2m] and
[6tt′ + 3b], respectively.[10]
Chart 1
Iridium(III) Emitters Bearing Nonplanar Tetradentate Ligands Formed
by Two Different Bidentate Moieties
Complex D can be viewed as a pseudo-tris(heteroleptic) iridium(III) emitter with the metal coordination
sphere formed by three different bidentate moieties, an orthometalated
2-phenylpyridine, an orthometalated 2-benzylpyridine type ligand,
and an acetylacetonate group (acac). Its lowest-unoccupied molecular
orbital (LUMO) is mainly centered on the orthometalated 2-phenylpyridine
moiety, specifically on the pyridyl group, whereas the highest-occupied
molecular orbital (HOMO) – 1 and HOMO lie at the metal center,
both metalated phenyl groups, and to a lesser extent at the acac group.
The green emission was attributed to a T1 excited state,
which is originated mainly by mixed HOMO – 1-to-LUMO and HOMO-to-LUMO
charge-transfer transitions. Therefore, in order to modify the emission
wavelength, two different actions could be performed: to introduce
substituents at the phenyl groups or to replace the pyridyl group
of the 2-phenylpyridine moiety with another heterocycle. In this context,
it should be mentioned that the presence of fluorine substituents
at the phenyl group of an orthometalated 2-phenylpyridine usually
produces a blue shift with regard to the unsubstituted chromophore,[7c,11] although their use is limited by issues involving partial defluorination
during the OLED assembly.[12] In contrast,
increasing the conjugation of the heterocycle by fused aromatic rings
gives rise to a red shift.[13] According
to this, we decided to replace the phenylpyridine unit of the tetradentate
ligand of complex D with a phenylisoquinoline group in
the search for red emitters with the structural rigidity of the latter.
Furthermore, we wished to investigate how the rigidity of the tetradentate
ligand predetermines the stereochemistry of the [6tt′ + 3b]
compound when an orthometalated 2-phenylpyridine is employed as a
3b ligand, what isomers can be obtained, and under what experimental
conditions.The present paper shows the preparation of an organic
molecule,
1-phenyl-3-(1-phenyl-1-(pyridine-2-yl)ethyl)isoquinoline (Chart ), which allows to
generate a new dianionic C,N,C′,N′-tetradentate 6tt′
ligand, formed by two different bidentate moieties. It also describes
its coordination to iridium and the stereocontrol in the formation
of the [6tt′ + 3b] isomers when an orthometalated 2-phenylpyridine
type ligand is used as the 3b unit. Furthermore, the photophysical
properties of the new compounds, including the fabrication of a PhOLED
device based on one of them, are reported.
Preparation
of 1-Phenyl-3-(1-phenyl-1-(pyridine-2-yl)ethyl)isoquinoline
(H2MeL)
This molecule was prepared according to Scheme . We initially performed
Pd(N-XantPhos)-catalyzed “deprotonative
cross-coupling processes”[14] involving 3-chloro-1-phenylisoquinoline and 2-benzylpyridine in
the presence of LiN(SiMe3)2 using cyclopentyl
methyl ether (CPME) as a solvent. The catalysis afforded 1-phenyl-3-(phenyl(pyridin-2-yl)methyl)isoquinoline
(H2L) as a yellow solid in 57% yield. The procedure had
been previously proved to be efficient for a variety of aryl halides
and substrates with weakly acidic C(sp3)–H bonds
including diarylmethanes,[15] allylbenzenes,[16] sulfoxides,[17] sulfones,[18] amides,[19] benzylic
phosphine oxides,[20] and η6-arene complexes of toluene derivatives and benzylic amines.[21] Furthermore, it had facilitated rapid access
to triarylmethanes with interesting biological activity.[22] In order to prevent the formation of trityl-type
radicals, the C(sp3)H-hydrogen atom was subsequently replaced
with a methyl group through its abstraction with lithium diisopropylamide
in tetrahydrofuran (THF) at −78 °C and posterior treatment
of the resulting anion with methyl iodide. After purification of the
reaction crude by silica gel column chromatography, the designed organic
molecule 1-phenyl-3-(1-phenyl-1-(pyridine-2-yl)ethyl)isoquinoline
(H2MeL) was obtained as a white solid in 70% yield.
Scheme 1
Synthesis of 1-Phenyl-3-(1-phenyl-1-(pyridine-2-yl)ethyl)isoquinoline
(H2MeL)
Coordination to Iridium
Once the desired organic molecule
was generated, we investigated its coordination to iridium with the
aim of preparing a dimer [Ir(μ-Cl)(6tt′)]2. It should allow us to enter in the chemistry of iridium(III) complexes
with the designed ligand. We were inspired by our previous work on
the related proligand 2-phenyl-6-(1-phenyl-1-(pyridin-2-yl)ethyl)pyridine.[10] Thus, in the search for the optimization of
the synthesis procedure, we selected the known dimers [Ir(μ-Cl)(η4-COD)]2 and [Ir(μ-Cl)(η2-COE)2]2 [COD = 1,5-cyclooctadiene (1), COE = cyclooctene (2)] as organometallic precursors
and studied their reactions with H2MeL in two different
alcohols, the usual one 2-ethoxyethanol and 1-phenylethanol (Scheme ).
Scheme 2
Synthesis of Complexes 3 and 4
Treatment of complex 1 with 1.0 equiv of H2MeL in 2-ethoxyethanol under reflux for 48 h leads to the carbonyl
derivative Ir(κ4-cis-C,C′-cis-N,N′-MeL)Cl(CO) (3), which was
isolated as an orange solid in 66% and characterized by X-ray diffraction
analysis. Figure displays
a view of the complex. The structure proves the presence of a carbonyl
group coordinated to iridium and the generation of a tetradentate
6tt′ ligand as a result of the N-coordination of both heterocycles
of the organic precursor and the activation of an ortho-CH bond of both phenyl groups. The polyhedron around the iridium
atom is the expected octahedron with the phenyl substituent of the
2-phenylisoquinoline moiety disposed trans to the pyridyl ring of
the 2-benzylpyridine moiety [C(1)–Ir–N(2) = 168.31(13)°].
The carbonyl group and the chloride anion lie in the plane perpendicular
to the C(1)–Ir–N(2) direction. They are disposed trans
to the isoquinolyl unit and the remaining phenyl group, with angles
C(29)–Ir–N(1) and Cl–Ir–C(19) of 169.88(14)
and 170.53(10)°, respectively. In accordance with the presence
of the carbonyl ligand, the infrared (IR) spectrum of the complex
contains a ν(CO) band at 2023 cm–1, whereas
the 13C{1H} NMR spectrum in dichloromethane-d2 shows a singlet at 172.6 ppm.
X-ray structure of 3 showing 50% thermal ellipsoid
probability (hydrogen atoms have been omitted). Selected bond lengths
(Å) and angles (degree): Ir–C(1) = 2.012(4), Ir–C(19)
= 2.035(3), Ir–C(29) = 1.849(4), Ir–N(1) = 2.054(3),
Ir–N(2) = 2.124(3), Ir–Cl = 2.4651(9); N(1)–Ir–N(2),
91.72(11); C(1)–Ir–N(2) = 168.31(13), C(29)–Ir–N(1)
= 169.88(14), Cl–Ir–C(19) = 170.53(10), N(1)–Ir–N(2)
= 91.72(11), C(1)–Ir–C(19) = 98.95(14), C(1)–Ir–N(1)
= 79.07(13), C(19)–Ir–N(1) = 81.92(13), C(19)–Ir–N(2)
= 86.73(13).The formation of 3 and its structure agree well with
those of the dipyridine counterpart complex C (Chart ), which was prepared
under similar conditions by reaction of 1 with 2-phenyl-6-(1-phenyl-1-(pyridin-2-yl)ethyl)pyridine.
In both cases, the carbonyl ligand comes from the solvent of the reaction.
The facility of iridium and platinum group metals to promote the dehydrogenation
of primary alcohols to aldehydes[23] and
the abstraction of the CO group from aldehydes[24] is well known. In contrast to 2-ethoxyethanol, the secondary
alcohol 1-phenylethanol does not undergo decarbonylation. Thus, the
reaction of 1 with H2MeL in this alcohol under
reflux for 3 days affords a brown solid, which corresponds to the
desired dimer [Ir(μ-Cl)(κ4-cis-C,C′-cis-N,N′-MeL)]2 (4), according to its MALDI-TOF spectrum ([M/2]+ 612.2) and C, H, N-elemental analysis. The yield of the preparation
is modest (34%). However, a significant improvement up to 82% is achieved
when, under the same conditions, COE-dimer 2 is used
as the organometallic precursor instead of complex 1.
Reactions and [6tt′ + 3b] Complexes Keeping the Disposition
of the Tetradentate Ligand
Having obtained the desired starting
compound [Ir(μ-Cl)(6tt′)]2, we next addressed
the task of replacing the chloride anion of the mononuclear unit with
a 3b ligand. The aim was to generate new species [6tt′ + 3b],
which would really be [3b + 3b′ + 3b″], since the 6tt′
ligand is certainly a [3b + 3b′] moiety. For this purpose,
we selected Kacac and Li[py-2-C6H4] as precursors
of the 3b ligand (Scheme ).
Scheme 3
Preparation of Complexes 5 and 6a
Treatment of dimer 4 with Kacac in THF at 60 °C
for 6 h leads to the acetylacetonate derivative Ir(κ4-cis-C,C′-cis-N,N′-MeL)(acac)
(5), which was isolated as a reddish brown solid in 80%
yield after silica column chromatography purification and characterized
by X-ray diffraction analysis. Its structure (Figure ) displays the same disposition for the donor
atoms of the tetradentate ligand as that observed in 3. Thus, the polyhedron around the metal center can be rationalized
as a distorted octahedron with the phenyl substituent of the 2-phenylisoquinoline
moiety disposed trans to the pyridyl ring of the 2-benzylpyridine
moiety [C(1)–Ir–N(2) = 170.90(13)°], whereas the
acac ligand lies at a perpendicular plane with the oxygen atoms O(1)
and O(2) situated trans to the isoquinolyl group [O(1)–Ir–N(1)
= 174.77(11)°] and to the phenyl of the benzyl moiety [O(2)–Ir–C(24)
= 172.29(13)°], respectively.
Figure 2
X-ray structure of 5, showing
50% thermal ellipsoid
probability (hydrogen atoms have been omitted). Selected bond lengths
(Å) and angles (degree): Ir–C(1) = 1.991(4), Ir–C(24),
1.996(4), Ir–N(1) = 1.970(3), Ir–N(2) = 2.128(3), Ir–O(1)
= 2.049(2), Ir–O(2), 2.135(3); C(1)–Ir–N(2) =
170.90(13), O(1)–Ir–N(1) = 174.77(11), O(2)–Ir–C(24)
= 172.29(13).
X-ray structure of 5, showing
50% thermal ellipsoid
probability (hydrogen atoms have been omitted). Selected bond lengths
(Å) and angles (degree): Ir–C(1) = 1.991(4), Ir–C(24),
1.996(4), Ir–N(1) = 1.970(3), Ir–N(2) = 2.128(3), Ir–O(1)
= 2.049(2), Ir–O(2), 2.135(3); C(1)–Ir–N(2) =
170.90(13), O(1)–Ir–N(1) = 174.77(11), O(2)–Ir–C(24)
= 172.29(13).The chloride anion of the mononuclear
units of 4 can
be similarly replaced with an orthometalated 2-phenylpyridine ligand.
In contrast to acac, this C,N-bidentate group is asymmetrical. Thus,
keeping the disposition of the tetradentate ligand, its coordination
can in principle afford two different isomers: one of them with the
N-heterocycles in fac disposition (6a) and the other
bearing the N-heterocycles in the mer position with the isoquinolyl
moiety of the tetradentate ligand trans disposed to the pyridyl ring
of the bidentate group (6b). Treatment of the dimer with
Li[py-2-C6H4] in THF at room temperature for
24 h produces the expected substitution and regioselectively gives
only one of the possible isomers of Ir(κ4-cis-C,C′-cis-N,N′-MeL){κ2-C,N-(C6H4-py)} (6), according to its 1H and 13C{1H} NMR spectra (Figures S58 and S59). This isomer was isolated as dark-red crystals,
suitable for X-ray diffraction analysis, in 20% yield after the purification
of the reaction crude by neutral-alumina column chromatography. Figure shows a view of
its structure, which reveals a fac disposition for the N-heterocycles
and therefore proves the formation 6a. Thus, the coordination
polyhedron around the iridium center can be rationalized as a distorted
octahedron with the pyridyl ring of the 3b ligand trans disposed to
the phenyl group of the benzyl moiety [N(3)–Ir–C(23)
= 175.77(10)°], the pyridyl ring of the 2-benzylpyridine moiety
situated in the trans position with respect to the phenyl substituent
of the 2-phenylisoquinoline moiety [N(2)–Ir–C(1) = 169.59(10)°],
and the latter trans disposed to the phenyl substituent of the 3b
ligand [N(1)–Ir–C(29) = 174.26(10)°].
Figure 3
X-ray structure
of 6a showing 50% thermal ellipsoid
probability (hydrogen atoms have been omitted). Selected bond lengths
(Å) and angles (degree): Ir–C(1) = 2.005(3), Ir–C(23)
= 2.023(3), Ir–C(29) = 2.032(3), Ir–N(1) = 2.067(2),
Ir–N(2) = 2.110(2), Ir–N(3) = 2.110(2); N(1)–Ir–C(29)
= 174.26(10), N(2)–Ir–C(1) = 169.59(10) N(3)–Ir–C(23)
= 175.77(10).
X-ray structure
of 6a showing 50% thermal ellipsoid
probability (hydrogen atoms have been omitted). Selected bond lengths
(Å) and angles (degree): Ir–C(1) = 2.005(3), Ir–C(23)
= 2.023(3), Ir–C(29) = 2.032(3), Ir–N(1) = 2.067(2),
Ir–N(2) = 2.110(2), Ir–N(3) = 2.110(2); N(1)–Ir–C(29)
= 174.26(10), N(2)–Ir–C(1) = 169.59(10) N(3)–Ir–C(23)
= 175.77(10).The regioselective formation of 6a must be highlighted.
Homoleptic emitters bearing the N-heterocycles in the fac position
are usual since this disposition appears to afford the most stable
isomer.[25] However, the heteroleptic emitters
of the class [3b + 3b + 3b′] with the N-heterocycles disposed
in position fac are very scarce,[4a,26] most probable
because the N-heterocycles are trans disposed in the starting compounds,
[Ir(μ-Cl)(3b)2]2, and once the kinetically
favored mer-emitters are formed, their mer–fac isomerization
has too high activation energy. In this context, it should be noted
that six-coordinate iridium(III) complexes exhibit a high octahedral
Δ0 splitting.[27] Thus,
the ligand-field stabilization energy makes these emitters inert toward
processes initiated by ligand dissociation reactions. As far as we
know, heteroleptic emitters [3b + 3b′ + 3b″] bearing
three different bidentate units with N-heterocycles fac disposed are
unknown until now.
Pyridyl-Benzyl Position Exchange in the Tetradentate
Ligand
We have previously reported that the acetonitrile-solvate
cation
[Ir{κ4-C,C,C′,C′-[C6H4Im(CH2)4ImC6H4]}(CH3CN)2]+ (Im = imidazolylidene)
facilitates the pyridyl-supported heterolytic ortho-CH bond activation of the phenyl group of 2-phenylpyridines to yield
the corresponding [6tt + 3b] emitters using a base such as (piperidinomethyl)polystyrene.
This bis(solvento) cation was prepared by abstraction of the iodide
ligand of the dimer [Ir(μ-I){κ4-C,C,C′,C′-[C6H4Im(CH2)4ImC6H4]}]2 with a silver salt in
acetone–dichloromethane, followed by the addition of acetonitrile.[7c] This precedent encouraged us to extend the methodology
to [6tt′ + 3b] emitters of heteroleptic tetradentate ligands,
with the aim of comparing the stereochemistry of the formed compounds
with that generated through Scheme .The same procedure starting from 4 affords the salt [Ir(κ4-cis-C,C′-cis-N,N′-MeL)(CH3CN)2]BF4 (7), which was isolated as an
orange solid in 87% yield. The presence of two inequivalent acetonitrile
ligands in the cation is supported by the 1H and 13C{1H} NMR spectra of the solid in dichloromethane-d2. The first spectrum displays two singlets
at 2.81 and 2.11 ppm corresponding to the methyl groups, whereas the
second one displays two singlets at 118.4 and 118.1 ppm due to C(sp)–carbon
atoms and two singlets at 4.7 and 3.5 ppm for the methyl groups. Although
complex 7 is a 6tt′-counterpart of the cation
[Ir{κ4-C,C,C′,C′-[C6H4Im(CH2)4ImC6H4]}(CH3CN)2]+, they do not display
the same behavior (Scheme ). Treatment of fluorobenzene solutions of 7 with
1.0 equiv of 2-phenylpyridine in the presence of (piperidinomethyl)polystyrene
under reflux for 48 h leads to a mixture of the mer isomer mer-Ir(κ4-cis-C,C′-cis-N,N′-MeL){κ2-C,N-(C6H4-py)} (6b) and the salt [Ir(κ3-C,N,N′;η2-C,C)-MeHL)(κ2-C,N-C6H4-py)]BF4 (8). Under the same conditions,
2-(p-tolyl)pyridine affords the mixture of the analogous-p-tolyl compounds: the mer isomer Ir(κ4-cis-C,C′-cis-N,N′-MeL){κ2-C,N-(C6H3Me-py)} (9b) and the salt [Ir(κ3-C,N,N’;η2-C,C)-MeHL)(κ2-C,N-C6H3Me-py)]BF4 (10). In the absence of
the base, using propan-2-ol under reflux as a solvent, salts 8 and 10 were selectively formed.
Scheme 4
Preparation
of Complexes 6b, 7, 8, 9b, and 10
Complexes 6b and 9b were separated from
the respective mixtures by basic-alumina column chromatography, employing
dichloromethane as the eluent, and isolated as dark-red solids in
11 and 12% yield, respectively. Both compounds were characterized
by X-ray diffraction analysis. Their structures demonstrate the mer
disposition of the N-heterocycles and reveal that the arrangement
of the donor atoms of the tetradentate ligand at the metal coordination
sphere does not change with respect to that observed in 3, 5, and 6a. A view of one of the two chemically
equivalent but crystallographically independent molecules of 6b and 9b, which are present in the respective
asymmetric units, is provided in Figures and 5. For both compounds,
the polyhedron around the iridium center can be described as a distorted
octahedron with the pyridyl ring of the 3b ligand trans disposed to
the isoquinolyl ring [N(1)–Ir(1)–N(3) = 175.0(3) and
175.6(3)° (6b), 174.27(11) and 175.49(10)°
(9b)], the pyridyl group of the 2-benzylpyridine fragment
situated in the trans position with respect to the phenyl substituent
of the 2-phenylisoquinoline moiety [N(2)–Ir(1)–C(1)
= 170.1(3) and 171.1(3)° (6b), 171.28(12) and 170.79(12)°
(9b)], and phenyl unit of the benzyl group trans disposed
to the phenyl substituent of the 3b ligand [C(19)–Ir(1)–C(29)
= 177.8(4) and 178.9(3)° (6b), 173.84(12) and 176.32(12)°
(9b)].
Figure 4
X-ray structure of one of the two independent molecules
of 6b showing 50% thermal ellipsoid probability (hydrogen
atoms
have been omitted). Selected bond lengths (Å) and angles (degree)
for both molecules: Ir(1)–C(1) = 1.993(9), 1.996(9), Ir(1)–C(19)
= 2.096(9), 2.118(9), Ir(1)–C(29) = 2.080(9), 2.071(9), Ir(1)–N(1)
= 1.984(7), 1.956(8), Ir(1)–N(2) = 2.126(7), 2.138(7), Ir(1)–N(3)
= 2.072(7), 2.063(7); N(1)–Ir(1)–N(3) = 175.0(3), 175.6(3),
N(2)–Ir(1)–C(1) = 170.1(3), 171.1(3), C(19)–Ir(1)–C(29)
= 177.8(4), 178.9(3).
Figure 5
X-ray structure of one
of the two independent molecules of 9b showing 50% thermal
ellipsoid probability (hydrogen atoms
have been omitted). Selected bond lengths (Å) and angles (degree)
for both molecules: Ir(1)–C(1) = 1.994(3), 1.998(3), Ir(1)–C(19)
= 2.098(3), 2.085(3), Ir(1)–C(29) = 2.083(3), 2.098(3), Ir(1)–N(1)
= 1.996(3), 2.000(3), Ir(1)–N(2) = 2.124(3), 2.126(3), Ir(1)–N(3)
= 2.073(3), 2.061(3); N(1)–Ir(1)–N(3) = 174.27(11),
175.49(10), N(2)–Ir–C(1) = 171.28(12), 170.79(12), C(19)–Ir(1)–C(29)
= 173.84(12), 176.32(12).
X-ray structure of one of the two independent molecules
of 6b showing 50% thermal ellipsoid probability (hydrogen
atoms
have been omitted). Selected bond lengths (Å) and angles (degree)
for both molecules: Ir(1)–C(1) = 1.993(9), 1.996(9), Ir(1)–C(19)
= 2.096(9), 2.118(9), Ir(1)–C(29) = 2.080(9), 2.071(9), Ir(1)–N(1)
= 1.984(7), 1.956(8), Ir(1)–N(2) = 2.126(7), 2.138(7), Ir(1)–N(3)
= 2.072(7), 2.063(7); N(1)–Ir(1)–N(3) = 175.0(3), 175.6(3),
N(2)–Ir(1)–C(1) = 170.1(3), 171.1(3), C(19)–Ir(1)–C(29)
= 177.8(4), 178.9(3).X-ray structure of one
of the two independent molecules of 9b showing 50% thermal
ellipsoid probability (hydrogen atoms
have been omitted). Selected bond lengths (Å) and angles (degree)
for both molecules: Ir(1)–C(1) = 1.994(3), 1.998(3), Ir(1)–C(19)
= 2.098(3), 2.085(3), Ir(1)–C(29) = 2.083(3), 2.098(3), Ir(1)–N(1)
= 1.996(3), 2.000(3), Ir(1)–N(2) = 2.124(3), 2.126(3), Ir(1)–N(3)
= 2.073(3), 2.061(3); N(1)–Ir(1)–N(3) = 174.27(11),
175.49(10), N(2)–Ir–C(1) = 171.28(12), 170.79(12), C(19)–Ir(1)–C(29)
= 173.84(12), 176.32(12).Cations of salts 8 and 10 are the result
of a hydrogen-transfer reaction at the metal coordination sphere from
the aryl substituent of the incoming pyridine ligand to the phenyl
unit of the benzyl group of the tetradentate ligand. In addition,
a position exchange between the pyridyl and phenyl rings of the 2-benzylpyridine
moiety takes place; that is, in contrast to the previous complexes
of this work, the phenyl substituent of the 2-phenylisoquinoline moiety
and the phenyl unit of the benzyl group are mutually trans disposed.
Both features were confirmed by the X-ray diffraction structure of
the cation of 8 (Figure ). Furthermore, the structure reveals that the incoming
pyridyl ring coordinates trans to the isoquinolyl group [N(3)–Ir–N(1)
= 172.17(11)°] as in mer isomers 6b and 9b. Thus, the octahedral environment of the iridium center is completed
with the phenyl substituent of the 3b ligand trans disposed to the
pyridyl ring of the 2-benzylpyridine moiety. The η2 coordination of the phenyl ring of the benzyl group to the iridium
atom is strongly supported by the bond lengths Ir–C(18) and
Ir–C(19) of 2.443(3) and 2.559(3) Å, d1 and d2, respectively, and
the Ir–C(23) separation of 3.225 Å (d3). It has been proposed that to calibrate low hapticities
of coordinated arene ligands, the three shortest M–C distances, d1 < d2 < d3, should be analyzed via the ρ1 and ρ2 parameters (eqs and 2). For an η2 coordination, it is fulfilled that d1 ≈ d2 < d3, and therefore, ρ2 > ρ1 ≈ 1.[28] For 8, the
calculated ρ2 and ρ1 values are
1.32 and 1.05, respectively, in agreement with that observed in the
few previously reported Ir(η2-arene) complexes.[29]
Figure 6
X-ray structure of the cation of 8 showing
50% thermal
ellipsoid probability (hydrogen atoms have been omitted). Selected
bond lengths (Å) and angles (degree): Ir–C(1) = 1.987(3),
Ir–C(18) = 2.443(3), Ir–C(19) = 2.559 (3), Ir–C(23)
= 3.225(3), Ir–C(29) = 2.012(3), Ir–N(1) = 2.016(3),
Ir–N(2) = 2.144(3), Ir–N(3) = 2.063(3); N(2)–Ir–C(29)
= 175.07(12), N(3)–Ir–N(1) = 172.17(11), C(1)–Ir–C(18)
= 155.22(13), C(1)–Ir–C(19) = 171.53(13).
X-ray structure of the cation of 8 showing
50% thermal
ellipsoid probability (hydrogen atoms have been omitted). Selected
bond lengths (Å) and angles (degree): Ir–C(1) = 1.987(3),
Ir–C(18) = 2.443(3), Ir–C(19) = 2.559 (3), Ir–C(23)
= 3.225(3), Ir–C(29) = 2.012(3), Ir–N(1) = 2.016(3),
Ir–N(2) = 2.144(3), Ir–N(3) = 2.063(3); N(2)–Ir–C(29)
= 175.07(12), N(3)–Ir–N(1) = 172.17(11), C(1)–Ir–C(18)
= 155.22(13), C(1)–Ir–C(19) = 171.53(13).The metal center of 8 and 10 increases
the acidity of the ortho-hydrogen atom of the coordinated
C–C double bond as a result of a transference of electrophilicity,
which makes it quite acidic. Thus, the treatment of the THF solutions
of the salts with 4.0 equiv of KOBu at
room temperature for 5 h causes its abstraction and the formation
of the respective [6tt′ + 3b] isomers 6c and 9c (Scheme ), which were isolated as dark-red solids in 75 and 80% yield, respectively.
Scheme 5
Preparation of Complexes 6c and 9c
The hydrogen abstraction is a stereochemically clean process, which
does not modify the mer disposition observed for the N-heterocycles
of the cation, as proved by the X-ray structure of 9c (Figure ). Thus,
the coordination polyhedron around the iridium atom of these other
mer isomers can be seen as a distorted octahedron with the isoquinolyl
group trans disposed to the pyridyl ring of the 3b ligand [N(1)–Ir–N(3)
= 176.0(3)°], whereas the phenyl substituent of the latter lies
trans to the pyridyl ring of the 2-benzylpyridine moiety [C(29)–Ir–N(2)
= 178.3(4)°]. The phenyl groups of the tetradentate ligand are
also mutually trans disposed [C(1)–Ir–C(19) = 169.8(4)°].
Figure 7
X-ray
structure of 9c showing 50% thermal ellipsoid
probability (hydrogen atoms have been omitted). Selected bond lengths
(Å) and angles (degree): Ir–C(1) = 2.079(10), Ir–C(19)
= 2.078(10), Ir–C(29) = 2.026(9), Ir–N(1) = 2.020(7),
Ir–N(2) = 2.140(8), Ir–N(3) = 2.060(7); N(1)–Ir–N(3)
= 176.0(3), C(29)–Ir–N(2) = 178.3(4), C(1)–Ir–C(19)
= 169.8(4).
X-ray
structure of 9c showing 50% thermal ellipsoid
probability (hydrogen atoms have been omitted). Selected bond lengths
(Å) and angles (degree): Ir–C(1) = 2.079(10), Ir–C(19)
= 2.078(10), Ir–C(29) = 2.026(9), Ir–N(1) = 2.020(7),
Ir–N(2) = 2.140(8), Ir–N(3) = 2.060(7); N(1)–Ir–N(3)
= 176.0(3), C(29)–Ir–N(2) = 178.3(4), C(1)–Ir–C(19)
= 169.8(4).Isomers a–c of these [6tt′ + 3b] emitters
are kinetically inert, and isomerization between them is not observed
in toluene, at reflux, after days. This is consistent with the previously
mentioned inertia of the iridium(III) octahedral complexes.
Photophysical
and Electrochemical Properties of the New Emitters
Figures S1–S9 show the UV–vis
spectra of 2-methyltetrahydrofuran (2-MeTHF) 1 × 10–4 M solutions of complexes 3, 5, 6a–c, 8, 9b,c, and 10. To their
rationalization, time-dependent density functional theory (DFT) (TD-DFT)
calculations [B3LYP-GD3//SDD(f)/6-31G**][5,7c,10] were also carried out, considering THF as a solvent.
Selected absorptions are listed in Tables and S1–S18, whereas frontier molecular orbitals are given in Figures S10–S19 and Tables S19–S27. The HOMO
spreads out over the metal center (30–50%), the phenyl groups
of the tetradentate ligand (25–50%), and the orthometalated
2-arylpyridine ligand (10–25%) for isomers 6 and 9 and cations 8 and 10. The LUMO
is located on the phenylisoquinoline moiety, about 70% on the heterocycle
and close to 20% on the phenyl substituent.
Table 1
Summary
of UV–vis Absorption
Data for Complexes 3, 5, 6a–c, 8, 9b,c, and 10 (in 2-MeTHF)
and Computed TD-DFT (in THF) Vertical Excitation Energies
λexp (nm)
ε (M–1 cm–1)
excitation
energy (nm)
oscillator strength (f)
transition
assignment
Complex 3
265
6708
262
0.118
HOMO – 9 → LUMO (31%), HOMO – 3 → LUMO + 2 (17%)
6tt′ + Cl → 6tt′
365
1700
379
0.0894
HOMO – 1 → LUMO (92%)
Ir + 6tt′ → 6tt′
416
8140
424 (S1)
0.0565
HOMO → LUMO (96%)
Ir + 6tt′ → 6tt′
550
90
549
(T1)
0
HOMO → LUMO (44%)
Ir + 6tt′ → 6tt′
HOMO – 1 → LUMO (42%)
Complex 5
242
31060
264
0.1216
HOMO – 9 → LUMO (46%)
6tt′ → 6tt′
442
3740
449
0.0782
HOMO – 1 → LUMO (82%)
Ir + 6tt′ + acac → 6tt′
484
2900
491 (S1)
0.0205
HOMO → LUMO (84%)
Ir + 6tt′ → 6tt′
600
170
606
(T1)
0
HOMO – 1 → LUMO (72%)
Ir + 6tt′ + acac → 6tt′
Complex 6a
267
7930
288
0.095
HOMO – 4 → LUMO (51%)
6tt′ + 3b → 6tt′ + 3b
435
1540
447
0.0564
HOMO – 1 → LUMO (89%)
Ir + 6tt′ + 3b → 6tt′
503
350
515 (S1)
0.0044
HOMO → LUMO (98%)
Ir + 6tt′ + 3b → 6tt′
590
70
590 (T1)
0
HOMO → LUMO (48%)
Ir + 6tt′ + 3b → 6tt′
HOMO – 2 → LUMO (24%)
Complex 6b
260
7055
266
0.0289
HOMO – 7 → LUMO + 2 (49%)
6tt′ + 3b → 6tt′
390
903
403
0.0491
HOMO – 2 → LUMO (93%)
Ir + 6tt′ + 3b → 6tt′
502
140
511 (S1)
0.0304
HOMO → LUMO (98%)
Ir + 6tt′ → 6tt′
574
33
593
(T1)
0
HOMO → LUMO (45%)
Ir + 6tt′ → 6tt′
HOMO – 1 → LUMO (37%)
Complex 6c
251
20000
267
0.0619
HOMO – 8 → LUMO + 2 (45%)
6tt′ + 3b → 6tt′+3b
399
5100
406
0.0932
HOMO – 2 → LUMO (89%)
Ir + 6tt′ → 6tt′
503
840
533 (S1)
0.0092
HOMO → LUMO (98%)
Ir + 6tt′ → 6tt′
600
220
608
(T1)
0
HOMO → LUMO (59%)
Ir + 6tt′ → 6tt′
HOMO – 2 → LUMO (32%)
Complex 8
254
10225
254
0.0107
HOMO – 6 → LUMO + 2 (54%)
6tt′ + 3b → 6tt′+3b
375
1860
387
0.0801
HOMO – 1 → LUMO (85%)
Ir + 3b → 6tt′
460
530
479 (S1)
0.0274
HOMO → LUMO (95%)
Ir + 3b → 6tt′
566
65
572
(T1)
0
HOMO → LUMO (53%)
Ir + 3b → 6tt′
HOMO – 1 → LUMO (36%)
Complex 9b
262
8104
268
0.016
HOMO – 7 → LUMO + 2 (56%)
6tt′ + 3b → 6tt′
394
1332
405
0.0517
HOMO – 2 → LUMO (92%)
Ir + 6tt′ + 3b → 6tt′
501
236
514 (S1)
0.0293
HOMO → LUMO (98%)
Ir + 6tt′ → 6tt′
569
84
594
(T1)
0
HOMO → LUMO (47%)
Ir + 6tt′ → 6tt′
HOMO – 1 → LUMO (35%)
Complex 9c
253
10440
267
0.0672
HOMO – 8 → LUMO + 2 (72%)
6tt′ + 3b → 6tt′ + 3b
410
1960
407
0.0868
HOMO – 2 → LUMO (86%)
Ir + 6tt′ → 6tt′
526
230
537 (S1)
0.0087
HOMO → LUMO (98%)
Ir + 6tt′ → 6tt′
590
60
611 (T1)
0
HOMO → LUMO (59%)
Ir + 6tt′ → 6tt′
HOMO – 2 → LUMO (32%)
Complex 10
233
16120
263
0.0513
HOMO – 8 → LUMO + 1 (47%)
6tt′ + 3b → 6tt′+3b
387
2420
387
0.0732
HOMO – 1 → LUMO (84%)
Ir + 3b → 6tt′
490
620
483
(S1)
0.0277
HOMO → LUMO (94%)
Ir + 3b → 6tt′
560
280
573 (T1)
0
HOMO → LUMO (53%)
Ir + 3b → 6tt′
HOMO – 1 → LUMO (36%)
The spectra can be properly analyzed by means of their
division
in three different regions: < 300, 300–550, and >550
nm.
The absorptions at the highest energy region are assignable to π–π*
intra- and interligand transitions. Bands between 300 and 500 nm result
from spin-allowed metal to ligand charge transfer along with intraligand
and ligand to ligand charge transfer. The very weak absorption tails
after 550 nm are ascribed to formally spin forbidden transitions,
mainly HOMO-to-LUMO and HOMO – 1-to-LUMO (3, 5, 6b, 8, 9b, and 10) or HOMO – 2-to-LUMO (6a, 6c, and 9c), caused by the large spin–orbit coupling
associated with the metal ion.The redox properties of complexes 3, 5, 6a–c, 8, 9b,c, and 10 were also evaluated
by cyclic voltammetry
to obtain more information on their frontier orbitals. Oxidation and
reduction potentials were measured under an argon atmosphere in acetonitrile
solutions, and the potentials were referenced versus Fc/Fc+. Figure S20 provides the cyclic voltammetry
traces, whereas Table lists the potential values. The table also includes the HOMO energy
levels estimated from the oxidation potentials and LUMO estimated
from both the reduction potential and the optical gap obtained from
the onset of emission, as well as DFT-calculated values.
Table 2
Electrochemical and DFT MO Energy
Data for Complexes 3, 5, 6a–c, 8, 9b,c, and 10
obs
(eV)
calcd
(eV)
complex
Eox (V)
Ered (V)
HOMOa
LUMOb
E00c
LUMO from E00
HOMO
LUMO
HLG
3
1.13
–1.93
–5.93
–2.87
2.17
–3.76
–5.70
–2.09
3.61
5
0.42d
–5.22
1.95
–3.27
–5.06
–1.79
3.27
6a
0.27d
–5.07
1.99
–3.08
–4.90
–1.77
3.13
6b
0.21
–2.28
–5.01
–2.52
2.00
–3.01
–4.91
–1.75
3.16
6c
0.11
–2.18
–4.91
–2.62
1.97
–2.94
–4.87
–1.82
3.05
8
1.04
–1.88, −2.42
–5.84
–2.92
2.13
–3.71
–5.73
–2.38
3.35
9b
0.20
–2.28
–5.00
–2.52
2.00
–3.00
–4.88
–1.74
3.14
9c
0.09
–2.19
–4.89
–2.61
1.97
–2.92
–4.85
–1.81
3.04
10
1.01
–1.88, −2.40
–5.81
–2.92
2.13
–3.68
–5.69
–2.37
3.32
HOMO = −[Eox vs Fc/Fc+ + 4.8] eV.
LUMO
= −[Ered vs Fc/Fc+ +
4.8] eV.
E00 =
onset of emission in THF at 77 K.
E1/2ox.
HOMO = −[Eox vs Fc/Fc+ + 4.8] eV.LUMO
= −[Ered vs Fc/Fc+ +
4.8] eV.E00 =
onset of emission in THF at 77 K.E1/2ox.All compounds
exhibit an Ir(III)/Ir(IV) oxidation peak. The nature
of the process and the potential value depend upon the compound class
and its stereochemistry. The oxidation of carbonyl derivative 3 is irreversible and takes place at 1.13 V. Cations 8 and 10 also undergo irreversible oxidation
at slight lower potentials, 1.01 and 1.04 V, respectively. In contrast,
the oxidation of acac-derivative 5 is reversible with E1/2ox = 0.42 V. The oxidation potential of the 2-phenylpyridine-type compounds 6a–c and 9b,c is between
0.09 and 0.27 V, being reversible for fac isomer 6a (E1/2ox = 0.27 V) and irreversible for the rest. The irreversible character
of the oxidation could be associated to some structural change in
the resulting unsaturated d5-species. It should be noted
that the trigonal prism is a usual polyhedron for unsaturated six-coordinated
compounds;[30] nevertheless, it could be
also a simple distortion of the original octahedron. These complexes
do not degrade in the cyclic voltammetry experiments. Multiple scans
provide similar voltammograms with a slight decrease of the oxidation
peak intensity, which is generally due to adsorption of the compound
on the electrode (Figure S21). Carbonyl
complex 3 displays irreversible reduction at −1.93
V, whereas cations 8 and 10 undergo two
irreversible reductions at about −2.41 and −1.88 V.
Mer isomers 6b,c and 9b,c show an irreversible reduction between −2.18 and
−2.28 V. On the other hand, reduction is not observed for acac
compond 5 and fac isomer 6a. Both the experimental
and DFT-calculated HOMO–LUMO gaps decrease in the sequence
of 3 > 8 ≈ 10 > 5 > 6b ≈ 9b ≈ 6a > 6c ≈ 9c.Complexes 3, 5, 6a–c, 8, 9b,c, and 10 are red
phosphorescent emitters (601–732 nm) when photoexcited in a
doped poly(methylmethacrylate) (PMMA) film at 5 wt % at room temperature
and 2-methyltetrahydrofuran at room temperature and at 77 K (Figures S23–S49). Table gathers the experimental and calculated
wavelengths, observed lifetimes, quantum yields, and radiative and
nonradiative rate constants.
Table 3
Emission Data for
Complexes 3, 5, 6a–c, 8, 9b,c, and 10
complex
calcd λem (nm)
media (T/K)
λem (nm)
τ (μs)
Φ
kra (s–1)
knra (s–1)
kr/knr
3
626
PMMA (298)
645
1.4
0.08
5.7 × 104
6.6 × 105
0.1
2-MeTHF (298)
645
2.6
0.13
5.0 × 104
3.4 × 105
0.2
2-MeTHF (77)
601, 647
3.8
5
691
PMMA (298)
681
0.7
0.57
8.1 × 105
6.1 × 105
1.3
2-MeTHF (298)
682
0.8
0.58
7.4 × 105
5.3× 105
1.4
2-MeTHF (77)
665, 715
1.2
6a
672
PMMA (298)
679, 720
0.9
0.17
1.9 × 105
9.2 × 105
0.2
2-MeTHF (298)
676
1.5
0.25
1.7 × 105
5.0 × 105
0.3
2-MeTHF (77)
650, 701
1.8
6b
677
PMMA (298)
663
1.2
0.29
2.4 × 105
5.9 × 105
0.4
2-MeTHF (298)
668
2.3
0.22
9.6 × 104
3.4 × 105
0.3
2-MeTHF (77)
646, 699
6c
699
PMMA (298)
694, 715
4.6
0.16
3.5 × 104
1.8 × 105
0.2
2-MeTHF (298)
692
2.0
0.12
0.6 × 104
4.4 × 105
0.1
2-MeTHF (77)
668, 709
1.3
8
645
PMMA (298)
669
1.4
0.18
1.3 × 105
5.9 × 105
0.2
2-MeTHF (298)
663
1.6
0.17
1.1 × 105
5.2 × 105
0.2
2-MeTHF (77)
617, 647
2.7
9b
676
PMMA (298)
663
1.6
0.23
1.4 × 105
4.8 × 105
0.3
2-MeTHF (298)
668
1.5
0.38
2.5 × 105
4.1 × 105
0.6
2-MeTHF (77)
649, 698
2.2
9c
695
PMMA (298)
681
2.1
0.13
6.2 × 104
4.1 × 105
0.2
2-MeTHF (298)
732
1.4
0.14
1.0 × 105
6.1 × 105
0.2
2-MeTHF (77)
671, 729
10
652
PMMA (298)
678
1.2
0.16
1.3 × 105
7.0 × 105
0.2
2-MeTHF (298)
666
1.8
0.19
1.1 × 105
4.5 × 105
0.2
2-MeTHF (77)
608, 652
3.6
Calculated according to kr = ϕ/τ and knr = (1
– ϕ)/τ.
Calculated according to kr = ϕ/τ and knr = (1
– ϕ)/τ.There is good agreement between the experimental wavelengths and
those obtained by estimating the difference in energy between the
optimized triplet states T1 and the singlet states S0 in THF, suggesting that the emissions can be ascribed to
T1 excited states. The emission depends upon the chemical
nature of the emitter and the stereochemistry of the isomer (Figure ). Thus, the wavelength
of the emission maximum is slightly orange-shifted in the sequence
of 6 ≈ 5 < 8 < 3, in good agreement with the observed increase of the HOMO–LUMO
gap; that is, phenylpyridine complexes ≈ acac derivative <
cationic species < carbonyl compound (Figure a). The emission maximum of isomers b also undergoes orange shift with regard to those of isomers a and c (Figure b,c).
Figure 8
(a) Emission spectra of 3, 5, 6a, and 8 in 5 wt % PMMA films at 298
K. (b) Emission
spectra of isomers 6a−c in 5 wt % PMMA films at
298 K. (b) Emission spectra of 6b,c, and 9b,c in 2-Me-THF at 77K.
(a) Emission spectra of 3, 5, 6a, and 8 in 5 wt % PMMA films at 298
K. (b) Emission
spectra of isomers 6a−c in 5 wt % PMMA films at
298 K. (b) Emission spectra of 6b,c, and 9b,c in 2-Me-THF at 77K.In contrast, the incorporation
of a methyl substituent at the phenyl
group of the 3b phenylpyridine ligand does not affect the wavelength
of the emission (Figure c). A similar result has been observed for complexes Ir(acac){κ2-C,N-(C6RH3-py)}{κ2-C,N-(C6H4-py)} (R = Me, Ph), which display almost
identical emissions despite the different substitution at the phenyl
group of one of the orthometalated 2-phenylpyridine ligand.[4d] The lifetimes are short and lie in a narrow
range of 0.7–4.6 μs. The quantum yields also depend upon
the chemical nature of the emitter. Those of acac derivative 5 are particularly noticeable, about 0.60 in both 5 wt % PMMA
film and 2-methyltetrahydrofuran, which compare well with the quantum
yields reported for complex Ir{κ2-C,N-(C6H4-isoqui)}2{κ2-O,O-[OC(CO2CH3)CHC(OCH3)O]}, bearing two orthometalated
2-phenyl-isoquinoline ligands and an asymmetrical acac group with
an electron-acceptor carboxylate and an electron-donor methoxy as
substituents at the carbonyl groups.[13k] Salts 8 and 10 as well as the isomers
of the 2-arylpyridine derivatives 6 and 9 display quantum yields in the range of 0.38–0.12. This significant
decrease appears to be a consequence of the decrease of the radiative
constant as a result of the replacement of the acac group with the
C,N-donor ligand.
Electroluminescence Properties of an OLED
Device Based on 5
Since acac derivative 5 exhibits
the highest photoluminescence
quantum yield of the prepared [6tt′ + 3b] compounds, we decided
to evaluate it as an emitter in a PhOLED device and to compare it
with one based on the known [3b + 3b + 3b′] red emitter Ir{κ2-C,N-(C6H4-isoqui)}2(acac) (11).[13a−13c,13f−13h,13l] The emitters have been tested
in bottom emission OLED structures. The devices were fabricated by
high-vacuum thermal evaporation. The anode was 1150 Å of indium
tin oxide (ITO). The cathode comprised 10 Å of LiF, followed
by 1000 Å of aluminum. The organic stack of the devices consisted
of, sequentially from the anode, 100 Å of HAT-CN (dipyrazino[2,3-f:2′,3′-h]-quinoxaline-2,3,6,7,10,11-hexacarbonitrile)
as the hole injection layer (HIL), 400 Å of NPD [N,N′-bis(naphthalen-1-yl)-N,N′-bis(phenyl)benzidine] as a hole-transporting
layer (HTL), 300 Å of an emissive layer (EML) containing BAlq2 (bis(2-methyl-8-quinolinolate)-4-(phenylphenolato)aluminum)
as a host doped with the red emitter (9%), and 550 Å of Alq3 as an electron-transporting layer (ETL). Red emitters 5 and 11 were compared side by side in the same
structure. Figure shows the schematic structure and energy levels of the devices and
the molecular structures of the materials used.
Figure 9
Device structure, energy
levels (eV), and molecular structures
of the materials used.
Device structure, energy
levels (eV), and molecular structures
of the materials used.The electroluminescence
(EL) and current density–voltage–luminance
(J–V–L) characteristics of the devices were tested upon manufacture. The
performance data of both devices are shown in Table and Figure . The EL spectrum of the device doped with 5 shows a peak at 672 nm, which is in agreement with its photoluminescence
spectra. It is 42 nm red-shifted and 40 nm broader with respect to
that of reference compound 11 (Figure a). The EL spectrum of the device based
on 5 contains some emission with a peak wavelength of
530 nm. It can be attributed to emission form Alq3 ETL.
Therefore, likely due to the fairly deep HOMO level of 5, −5.22 eV, the
holes cannot be trapped efficiently in the EML and can lead to Alq3 ETL causing some recombination and emission in this layer.
An external quantum efficiency (EQE) of 3.4% at 10 mA/cm2 was achieved in the device with 5 as the emitter versus
12.4% for 11 (Figure b). Both devices display a very similar profile for
current density (J) versus voltage (V) (Figure c). However,
the brightness (L) is lower for the device doped
with 5 compared to that of the device doped with 11 (Figure d). Due to the fact that a significant part of the 5 emission is outside the visible range (>780 nm), the luminance
efficacy
(LE, Figure e) and
power efficacy (PE, Figure f) of this emitter device are expected to be low. Recent OLED
devices based on [3b + 3b + 3b′] iridium emitters, with similar
CIE coordinates, exhibit EQEs and brightnesses in the ranges of 0.2–31.2%
and 288–48617 cd/m2, respectively.[5,31] Both devices were life-tested at room temperature under accelerated
conditions of a current density of 80 mA/cm2. The time
at which luminance falls to 95% of its initial value, LT95%, at 10 mA/cm2 was calculated assuming an acceleration
factor 2. As can be seen in Table and Figure , the LT95% at the same operating current density
is notably higher for the OLED based on 5 (393 h for 5 vs 186 h for 11 at 80 mA/cm2). The
LT95% improvement of 5 with regard to 11 could be explained by the significantly lower exciton energy
for 5, which is red-shifted with regard to 11. In this context, it should be noted that a higher-energy exciton
causes more damage to the device.[32]
Table 4
EL Performance of the Devices Based
on 5 and 11
1931
CIE
at
10 mA/cm2
at
80 mA/cm2
emitter (9%)
λmax (nm)
fwhma (nm)
CIE x
CIE y
voltage (V)
LEb (cd/A)
EQEc (%)
PEd (lm/W)
LT95%e (h)
L0f (cd/m2)
LT95%e (h)
5
672
118
0.556
0.390
8.2
0.9
3.4
0.3
17724
603
393
11
630
78
0.674
0.323
8.4
8.5
12.4
3.2
7522
5458
186
Full width at half-maximum of the
emission peak in the electroluminescence spectrum.
Luminous efficacy.
External quantum efficiency.
Power efficacy.
Lifetime as the time the luminance
falls to 95% of its initial value.
Initial luminance.
Figure 10
Performance
of the devices based on complex 5 (red
triangles) and 11 (blue circles): (a) EL spectra. (b) EQE vs J, (c) J vs V, (d) L vs V, (e) LE vs L, (f) PE vs L.
Figure 11
Normalized
luminance of the devices based on complex 5 (red triangles)
and 11 (blue circles) vs time at a
constant current density of 80 mA/cm2.
Performance
of the devices based on complex 5 (red
triangles) and 11 (blue circles): (a) EL spectra. (b) EQE vs J, (c) J vs V, (d) L vs V, (e) LE vs L, (f) PE vs L.Normalized
luminance of the devices based on complex 5 (red triangles)
and 11 (blue circles) vs time at a
constant current density of 80 mA/cm2.Full width at half-maximum of the
emission peak in the electroluminescence spectrum.Luminous efficacy.External quantum efficiency.Power efficacy.Lifetime as the time the luminance
falls to 95% of its initial value.Initial luminance.
Concluding
Remarks
This study has shown that the new organic molecule
1-phenyl-3-(1-phenyl-1-(pyridine-2-yl)ethyl)isoquinoline,
which was prepared by means of a palladium-catalyzed “deprotonative cross-coupling process”,
reacts with the iridium-diolefin precursor [Ir(μ-Cl)(η2-COE)2]2 to afford an [Ir(μ-Cl)(6tt′)]2 dimer as a consequence of the orthometalation of the phenyl
groups and the coordination of the N-heterocycles. This dimer allows
to access iridium(III) red emitters of the type [6tt′ + 3b],
which really are tris-heteroleptic [3b + 3b′ + 3b″],
since the tetradentate 6tt′ ligand is certainly a [3b + 3b′]
ensemble formed by two different units: an orthometalated 2-phenylisoquinoline
and an orthometalated 2-benzylpyridine. The bidentate 3b donor is
an acac group or an orthometalated 2-phenylpyridine-type ligand.The link between the orthometalated 2-phenylisoquinoline and 2-benzylpyridine
units reduces the number of possible stereoisomers of the structure
[6tt′ + 3b] with respect to a [3b + 3b′ + 3b″]
emitter bearing three free bidentate 3b units, and further, it permits
a noticeable stereocontrol. Thus, from the four possible dispositions
that are conceivable for a [3b + 3b′] ensemble formed by free
3b and 3b′ ligands such as an orthometalated 2-phenylisoquinoline
and an orthometalated 2-benzylpyridine (phenyl-trans-pyridine, phenyl-trans-phenyl, phenyl-trans-isoquinoline, and pyridine-trans-isoquinoline),
only the first two are observed for the 6tt′ ligand in the
[6tt′ + 3b] emitters, with clearly the first of them being
the most common. The phenyl-trans-phenyl disposition
is generated from the phenyl-trans-pyridine one and
involves a position exchange between the pyridyl and phenyl rings
of the 2-benzylpyridine unit. The exchange is produced in reactions
of a cationic solvate precursor [Ir(6tt′)S2]+ with 2-phenylpyridine-type molecules. These reactions involve
a hydrogen transfer from the aryl substituent of the incoming pyridine
ligand to the phenyl unit of the benzyl group of the tetradentate
ligand on the metal coordination sphere. The hydrogen transfer affords
an η2-arene synthetic intermediate, which yields
the final product by deprotonation of the coordinated double bond
of the arene. It occurs at a moderate temperature, about 80 °C,
which favors the formation of mer isomers with the incoming heterocycle
trans disposed to the isoquinoline moiety. At room temperature, the
preparation of fac isomers [6tt′ + 3b] is also possible through
direct substitution of the chloride anion of the dimer [Ir(μ-Cl)(6tt′)]2 with an orthometalated 2-phenylpyridine ligand.The
phosphorescent emitter resulting from the replacement of the
chloride anion of the dimer [Ir(μ-Cl)(6tt′)]2 with an acac ligand, which displays a phenyl-trans-pyridine disposition for the tetradentate ligand, is notable, and
its quantum yield of about 0.60 should be highlighted. Furthermore,
it proves to have applicability to the fabrication of OLED devices.
The OLED with such an emitter (λmax 672 nm) revealed
a 3.4% EQE at an operating current density of 10 mA/cm2.In summary, here, we describe the synthesis of a new organic
molecule
that allows the preparation of red phosphorescent emitters of iridium(III),
with three different bidentate units, and a better stereocontrol of
the resulting structures. Its coordination to iridium, the synthesis
of the emitters, their photophysical properties, and the applicability
to the fabrication of OLED devices of one of them are also included
as a proof-of-concept validation.
Experimental
Section
The starting compounds [Ir(μ-Cl)(η4-COD)]2 (1),[33] [Ir(μ-Cl)(η2-COE)2]2 (2),[34] and 3-chloro-1-phenylisoquinoline[35] were prepared by published methods. Chemical
shifts and coupling constants in the NMR spectra (Figures S50–S73) are given in ppm and Hz, respectively.
Synthesis
of 1-Phenyl-3-(phenyl(pyridin-2-yl)methyl)isoquinoline
(H2L)
Lithium bis(trimethylsilyl)amide (1 M, 2.635
mL, 2.635 mmol) was added dropwise over 10 min to a mixture of palladium(II)
acetate (14.09 mg, 0.063 mmol) and 4,6-bis(diphenylphosphino)phenoxazine
(N-XantPhos, 34.6 mg, 0.063 mmol) in CPME (6 mL). 2-Benzylpyridine
(201 μL, 1.255 mmol) was added to this reaction mixture, followed
by 3-chloro-1-phenylisoquinoline (300 mg, 1.255 mmol) in 5 mL of CPME,
and it was heated to 60 °C for 2 h. The reaction mixture was
cooled to room temperature and quenched slowly with 3 M HCl/MeOH to
a pH of 7. Then, it was concentrated, and the crude was purified by
column chromatography (silica gel) using n-hexane/dichloromethane
(gradient elution from 100 to 30% n-hexane). The
pure fractions were combined and concentrated to give a foamy yellow
solid (266.3 mg, 57%). HRMS (electrospray, m/z): calcd for C27H21N2 [M
+ H]+, 373.1699; found, 373.1682. 1H NMR NMR
(400 MHz, CDCl3, 298 K): δ 8.65 (ddd, J = 4.9, 1.9, 0.9, 1H), 8.11 (d, J = 8.5, 1H), 7.81
(d, J = 8.4, 1H), 7.71–7.63 (m, 4H), 7.57–7.49
(m, 5H), 7.42–7.36 (m, 5H), 7.32–7.27 (m, 1H), 7.19
(ddd, J = 7.5, 4.9, 1.1, 1H), 6.12 (s, 1H). 13C NMR (75 MHz, CDCl3, 298 K): δ 162.8, 160.2,
154.7 (all Cq), 149.3 (CH), 142.3, 139.8, 137.6 (all Cq), 136.5, 130.3 (2C), 129.9, 129.6 (2C), 128.5 (3C), 128.3
(2C), 127.4, 126.9, 126.7 (all CH), 125.4 (Cq), 124.5,
121.6, 119.6, 61.6 (all CH).
Synthesis of 1-Phenyl-3-(1-phenyl-1-(pyridine-2-yl)ethyl)isoquinoline
(H2MeL)
Lithium chloride (68 mg, 1.62 mmol) was
added to a solution of H2L (300 mg, 0.81 mmol) in 5 mL
of THF, and the reaction mixture was cooled to −78 °C.
Lithium diisopropylamide (2 M, 3.24 mL, 1.62 mmol) was added dropwise
over 10 min; then, the reaction mixture was kept at −78 °C
for 1 h. Methyl iodide (100 μL, 1.62 mmol) was added dropwise
over 5 min. The mixture was stirred at −78 °C for 30 min,
warmed to room temperature, quenched with saturated aqueous NH4Cl, and extracted with EtOAc. The organic fractions were dried
with MgSO4 and concentrated. The crude was purified by
column chromatography (silica gel) using 0–30% EtOAc/n-hexane to give a white solid (217.9 mg, 70%). HRMS (electrospray, m/z): calcd for C28H23N2 [M + H]+, 387.1856; found, 387.1840. 1H NMR (300 MHz, CD2Cl2): δ 8.61
(m, 1H), 8.14 (m, 1H), 7.77 (m, 1H), 7.71–7.67 (m, 2H), 7.65–7.62
(m, 1H), 7.60–7.57 (m, 1H), 7.56–7.49 (m, 4H), 7.40
(s, 1H), 7.37–7.22 (m, 6H), 7.17–7.14 (m, 1H), 2.43
(s, 3H). 13C NMR (75 MHz, CD2Cl2):
δ 167.5, 159.7, 159.6 (all Cq), 149.2 (CH), 148.8,
140.4, 137.8 (all Cq), 136.2, 130.7 (2C), 130.3, 129.4
(2C), 129.0, 128.7 (2C), 128.5 (2C), 127.9, 127.6, 127.5, 126.6 (all
CH), 125.4 (Cq), 124.5, 121.6, 119.2 (all CH), 58.1 (Cq), 28.6 (CH3).
Preparation of IrCl(κ4-cis-C,C′-cis-N,N′-MeL)(CO) (3)
Complex 1 (250 mg, 0.372 mmol) and H2MeL (and 287.7 mg, 0.744 mmol)
in 5 mL of 2-ethoxyethanol
were heated under reflux. After 48 h, an orange solid precipitated,
which was separated by decantation, washed with methanol (3 ×
5 mL), and dried under vacuum. Yield: 314 mg (66%). Crystals of 3 suitable for X-ray diffraction analysis were formed by diffusion
of pentane into a dichloromethane solution of the precipitate at 4
°C. Anal. Calcd for C29H20IrClN2O: C, 54.41; H, 3.15; N, 4.38. Found: C, 54.73; H, 3.19; N, 4.12.
HRMS (electrospray, m/z): calcd
for C30H23IrN3 [M–Cl–CO
+ CH3CN]+, 618.1517; found, 618.1513. Td5 = 385 °C.[35] IR (cm–1): ν (CO) 2023 (s). 1H NMR (300 MHz, CD2Cl2, 298 K): δ 9.31
(d, J = 8.1, 1H), 8.89 (d, J = 7.8,
1H), 8.20 (d, J = 7.9, 1H), 8.16 (dd, J = 7.6, 1.2, 1H), 8.03–7.90 (m, 3H), 7.81 (s, 1H), 7.81–7.69
(m, 3H), 7.42 (dd, J = 8.0, 1.4, 1H), 7.33–7.24
(m, 2H), 7.17 (m, 1H), 6.98 (m, 1H), 6.84 (m, 1H), 2.72 (s, 3H, MeL).13C{1H} NMR (101 MHz, CD2Cl2): δ 172.6 (CO), 169.4, 159.4 (both Cq), 157.1 (CH), 152.5, 147.8, 147.1 (all Cq), 140.4
(CH), 139.5 (Cq), 138.9 (CH), 138.8 (Cq), 137.7
(CH), 133.3 (Cq), 132.7, 131.1, 130.7, 129.2, 128.5, 127.4,
126.7 (all CH), 125.6 (Cq), 125.0, 124.8, 124.7, 123.7,
121.9, 115.6 (all CH), 59.0 (Cq), 23.1 (MeL).
Preparation of [Ir(μ-Cl)(κ4-cis-C,C′-cis-N,N′-MeL)]2 (4)
Complex 1 (375 mg, 0.558 mmol) or 2 (500 mg, 0.558 mmol) and H2MeL (430 mg, 1.11
mmol) in 7 mL of 1-phenylethanol were stirred at 140 °C. After
72 h, a brown solid was formed, separated by decantation, and washed
with diethyl ether until mother liquors were colorless. Yield: 230
mg (34%) starting from 1, 557 mg (82%) starting from 2. Anal. Calcd for C56H40Cl2Ir2N4: C, 54.94; H, 3.29; N, 4.58. Found: C,
55.03; H, 3.10; N, 4.38. MS (MALDI-TOF, m/z): calcd for C28H20ClIrN2 [M/2]+, 612.1; found, 612.2.
Preparation of Ir(κ4-cis-C,C′-cis-N,N′-MeL)(acac) (5)
Acetylacetone (350
μL, 3.41 mmol) and KOH (225 mg, 3.41 mmol)
in 4 mL of methanol were poured into a suspension of 4 (557 mg, 0.45 mmol) in 15 mL of THF. The mixture was stirred at
60 °C for 6 h. The solvent was removed under vacuum to afford
an orange residue, which was treated with 15 mL of dichloromethane.
The suspension formed was filtered over Celite, and the resulting
solution was concentrated under vacuum. The addition of 5 mL of pentane
yielded a reddish brown solid, which was purified by column chromatography
(silica gel) using dichloromethane as the eluent. Yield: 492 mg (80%).
X-ray quality crystals were obtained by evaporation in dichloromethane
at 4 °C. Anal. Calcd for C33H27IrN2O2: C, 58.65; H, 4.03; N, 4.15. Found: C, 58.31;
H, 3.99; N, 4.25. HRMS (electrospray, m/z): calcd for C33H27IrN2O2 [M + Na]+, 699.1596; found, 699.1601. Td5 = 360 °C.[36] IR (cm–1): ν(C=O) 1574 (s), 1508 (s). 1H
NMR (400 MHz, CD2Cl2, 298 K): δ 8.81 (m,
1H), 8.25 (m, 1H), 8.18 (d, J = 7.8, 1H), 7.89–7.80
(m, 3H), 7.78 (dd, J = 7.4, 1.5, 1H), 7.65 (s, 1H),
7.62 (m, 2H), 7.55 (dd, J = 6.7, 2.3, 1H), 7.24 (m,
2H), 7.15 (ddd, J = 7.3, 7.3, 1.3, 1H), 7.08 (ddd, J = 7.8, 1.6, 1H), 6.85–6.76 (m, 2H), 5.48 (s, 1H,
CH acac), 2.68 (MeL), 2.20, 1.58 (both s, 3H each,
CH3 acac). 13C{1H} NMR (101 MHz,
CD2Cl2): δ 185.3, 184.9 (both CO acac),
171.7, 163.7, 161.5, 152.0 (all Cq), 151.5 (CH), 149.1,
140.6 (both Cq), 138.0 (CH), 137.4, 137.0 (both Cq), 136.2, 134.1, 130.7, 129.5, 128.5, 128.2, 127.9, 125.6, 125.3
(all CH), 125.2 (Cq), 124.4, 122.9, 122.8, 122.1, 121.3,
114.4 (all CH), 101.4 (CH acac), 58.6 (Cq), 28.6, 28.3
(both CH3 acac), 23.3 (MeL).
Preparation
of fac-Ir(κ4-cis-C,C′-cis-N,N′-MeL)(κ2-C,N-C6H4-py) (6a)
A solution of 2-(2-bromophenyl)pyridine
(81.6 μL, 0.488 mmol) in 5 mL of THF was cooled to −78
°C, and n-BuLi (321 μL, 1.6 M in hexanes,
0.512 mmol) was added dropwise. After stirring at the same temperature
for 1 h, a precooled (−78 °C) suspension of 4 (0.122 mmol) in 5 mL of THF was cannula-transferred into the lithiation
flask, and the mixture was allowed to slowly warm to room temperature
over 18 h. The solvent was then evaporated. The residue was extracted
with dichloromethane (3 × 10 mL) and purified by flash column
chromatography using a 3:1 mixture of dichloromethane/pentane, affording
compound 6a as a dark-red solid. Yield: 35 mg (20%).
X-ray quality crystals of 6a were obtained in dichloromethane
by evaporation at room temperature. Anal. Calcd for C39H28IrN3: C, 64.09; H, 3.86; N, 5.75. Found:
C, 64.17; H, 4.02; N, 5.98. HRMS (electrospray, m/z): calcd for C39H29IrN3 [M + H]+, 732.1963; found, 732.1924. Td5 = 305 °C.[36]1H NMR (400 MHz, CD2Cl2, 298 K): δ 8.86
(m, 1H), 8.15 (d, J = 7.3, 1H), 8.09 (d, J = 7.5, 1H), 7.99 (m, 1H), 7.96–7.87 (m, 5H), 7.72–7.63
(m, 3H), 7.56–7.50 (m, 2H), 7.37 (m, 1H), 7.24–7.16
(m, 3H), 7.09 (d, J = 7.5, 1H), 6.87–6.80
(m, 3H), 6.75 (t, J = 7.3, 1H), 6.63–6.58
(m, 2H), 2.76 (s, 3H, MeL). 13C NMR (75
MHz, CD2Cl2): δ 168.8, 167.7, 167.1, 164.7,
161.6 (all Cq), 151.2 (CH), 150.8, 150.0, 147.8 (all Cq), 147.7 (CH), 146.1, 140.7 (both Cq), 139.1 (CH),
137.8 (Cq), 137.7, 137.0, 136.9, 136.7, 130.7, 130.1, 130.1,
129.1, 128.5, 127.9, 126.0, 125.9, 125.3, 123.3, 122.8 (all CH), 122.7
(Cq), 122.0, 121.6, 121.4, 120.8, 119.2, 114.6 (all CH),
59.6 (Cq) 24.1 (MeL).
Preparation
of [Ir(κ4-cis-C,C′-cis-N,N′-MeL)(CH3CN)2]BF4 (7)
Silver tetrafluoroborate
(95.4 mg, 0.490 mmol) dissolved in acetone (5 mL) was added to 4 (300 mg, 0.245 mmol) in dichloromethane (15 mL). The mixture
protected from light was stirred for 5 h and filtered through Celite
to remove the formed silver chloride. The solution was concentrated
under vacuum. The addition of 3 mL of diethyl ether afforded an orange
solid, which was dissolved in acetonitrile (5 mL) and filtered off.
The resulting solution was concentrated until about 0.5 mL. The subsequent
addition of 3 mL of diethyl ether gave an orange solid. Yield: 319
mg (87%). Anal. Calcd for C32H26BF4IrN4: C, 51.55; H, 3.51; N, 7.51. Found: C, 51.23; H,
3.71; N, 7.80. HRMS (electrospray, m/z): calcd for C30H23IrN3 [M–BF4–CH3CN]+, 618.1517; found, 618.1478. 1H NMR (300 MHz, CD2Cl2, 298 K): δ
9.23 (d, J = 7.9, 1H), 8.83 (m, 1H), 8.16 (d, J = 8.1, 1H), 8.03–7.91 (m, 4H), 7.83 (s, 1H), 7.80–7.72
(m, 2H), 7.55–7.50 (m, 2H), 7.31 (d, J = 9.2,
1H), 7.23 (m, 1H), 7.08 (m, 1H), 6.93–6.76 (m, 2H), 2.81 (s,
3H, CH3CN), 2.71 (s, 3H, MeL), 2.11 (s,
3H, CH3CN). 13C{1H} NMR (101 MHz,
CD2Cl2): δ 171.3 (Cq), 159.7
(Cq), 153.9 (CH), 150.0, 148.6, 140.5 (all Cq), 139.9 (CH), 138.0 (Cq), 134.7, 134.2 (both CH), 134.0
(Cq), 132.4 (CH), 130.4 (2 CH), 129.0, 128.5, 127.0 (all
CH), 125.7 (2 CH), 125.0 (Cq), 124.5, 124.1, 123.7, 122.0
(all CH), 118.4, 118.1 (both CH3CN) 115.9
(CH), 58.8 (Cq), 23.1 (MeL), 4.7, 3.5
(both CH3CN). One of the Cq signals of the tetradentate ligand is not observed because it is
overlapped with other signals.
Reaction of 7 with 2-Phenylpyridine:
Formation of mer-Ir(κ4-cis-C,C′-cis-N,N′-MeL){κ2-C,N-(C6H4-py)} (6b) and [Ir(κ3-C,N,N′;η2-C,C)-MeHL)(κ2-C,N-C6H4-py)]BF4 (8)
Complex 7 (300 mg,
0.402 mmol), 2-phenylpyridine (58.6 μL, 0.402
mmol), and (piperidinomethyl)polystyrene (115 mg, 0.402 mmol) were
stirred in 10 mL of fluorobenzene under reflux. After 48 h, the mixture
was cooled to room temperature and filtered through Celite, and the
resulting solution was concentrated. The residue was extracted with
dichloromethane. Addition of pentane (5 mL) led to a mixture of 6b and 8, which were separated by column chromatography
(neutral aluminum oxide) using dichloromethane as the eluent to afford 6b [dark-red solid, yield: 32 mg (11%)] and then acetonitrile
to obtain 8 [orange solid, yield: 51.2 mg (32%)]. X-ray
quality crystals of 6b were formed in dichloromethane
by evaporation at room temperature. Analytical and spectroscopic data
of 6b: Anal. Calcd for C39H28IrN3: C, 64.09; H, 3.86; N, 5.75. Found: C, 64.21; H, 4.03; N,
5.71. HRMS (electrospray, m/z):
calcd for C39H29IrN3 [M + H]+, 732.1987; found, 732.1960. Td5 = 336 °C.[36]1H NMR (400
MHz, CD2Cl2, 298 K): δ 9.43 (d, J = 5.6, 1H), 8.85 (d, J = 7.8, 1H), 8.11
(m, 2H), 7.97–7.86 (m, 4H), 7.83 (s, 1H), 7.77 (d, J = 7.7, 1H), 7.72–7.62 (m, 3H), 7.53 (m, 1H), 7.31
(dd, J = 5.5, 1.1, 1H), 7.18 (ddd, J = 7.3, 5.9, 1.5, 1H), 6.95–6.77 (m, 5H), 6.65 (m, 1H), 6.61
(m, 1H), 6.22 (d, J = 7.2, 1H), 2.80 (s, 3H, MeL). 13C NMR (101 MHz, CD2Cl2): δ 178.9, 171.1, 169.0, 168.3, 165.2, 161.9 (all Cq), 153.1 (CH), 150.9 (Cq), 150.2 (CH), 146.5, 145.0,
141.5 (all Cq), 138.3, 137.1, 137.0 (all CH), 136.5 (Cq), 133.3, 132.0, 130.3, 130.2, 129.3, 129.1, 128.2, 127.8,
125.9, 125.7 (all CH), 125.4 (Cq), 124.7, 123.2, 123.0,
122.8, 122.7, 121.8 (2C), 120.4, 119.7, 114.4 (all CH), 60.7 (Cq), 24.6 (MeL). For analytical and spectroscopic
data of 8, see below.
Preparation of [Ir(κ3-C,N,N′;η2-C,C)-MeHL)(κ2-C,N-C6H4-py)]BF4 (8)
A mixture of 7 (200 mg, 0.268 mmol)
and 2-phenylpyridine (42.5 μL, 0.268 mmol) was stirred in 10
mL of 2-propanol under reflux. After 48 h, an orange solid appeared,
which was separated by decantation, and it was washed with diethyl
ether (3 × 5 mL). Yield: 134 mg (61%). X-ray quality crystals
were obtained from dichloromethane–diethyl ether by diffusion
at 4 °C. Anal. Calcd for C39H29BF4IrN3: C, 57.22; H, 3.57; N, 5.13. Found: C, 56.92; H,
3.45; N, 5.08. HRMS (electrospray, m/z): calcd for C39H29IrN3 [M-BF4]+, 732.1987; found, 732.1973. IR (cm–1): ν (BF4) 1049 (s). 1H NMR (300 MHz,
CD2Cl2, 298 K): δ 9.02 (d, J = 5.6, 1H), 8.93 (d, J = 8.2, 1H), 8.81 (d, J = 5.1, 1H), 8.20 (m, 2H), 8.14 (m, 1H), 8.06 (s, 1H),
8.03–7.83 (m, 5H), 7.58 (m, 1H), 7.52 (m, 1H), 7.34 (d, J = 7.9, 1H), 7.15 (d, J = 8.0, 1H), 7.00
(dd, J = 7.2, 7.2, 1H), 6.86–6.73 (m, 2H),
6.68–6.54 (m, 3H), 6.42 (d, J = 7.7, 1H),
6.28 (m, 2H), 5.97 (d, J = 7.3, 1H), 2.34 (s, 3H, MeL). 19F NMR (282.38 MHz, CD2Cl2, 298 K): δ −153.17 (s). 13C NMR (100
MHz, CD2Cl2): δ 167.6, 167.0, 161.7, 156.2
(all Cq), 150.5, 149.4 (both CH), 148.3, 146.8, 145.1,
142.6 (all Cq), 141.1, 139.3 (both CH), 137.8 (Cq), 133.3, 132.9, 132.4, 131.4, 131.1 (3C), 131.0, 129.7, 129.7 (all
CH), 129.0 (Cq), 128.9 (2C), 126.1, 125.9, 125.6 (all CH),
125.0 (Cq), 124.0 (2C), 123.2, 123.1, 120.8, 117.4, 117.0
(all CH), 60.2 (Cq), 25.3 (MeL).
Preparation
of mer-Ir(κ4-trans-C,C′-cis-N,N′-MeL){κ2-C,N-(C6H4-py)} (6c)
KOBu
(41.5 mg, 0.368 mmol) dissolved in 5 mL of THF was slowly
added (5–10 min) to 8 (76 mg, 0.093 mmol) in 5
mL of THF. The initial orange/red suspension became a reddish-brown
solution. After 5 h, the solvent was removed under vacuum and the
product was extracted with dichloromethane (3 × 10 mL). The dichloromethane
solution was concentrated under vacuum. The addition of pentane yielded
a brown solid that was purified by column chromatography (basic alumina)
using dichloromethane as the eluent. A reddish-brown solid was obtained.
Yield: 51 mg (75%). Anal. Calcd for C39H28IrN3: C, 64.09; H, 3.86; N, 5.75. Found: C, 63.86; H, 3.99; N,
5.54. HRMS (electrospray, m/z):
calcd for C39H29IrN3 [M + H]+, 732.1987; found, 732.1946. Td5 = 322 °C.[36]1H NMR (300
MHz, CD2Cl2, 298 K): δ 9.16 (d, J = 5.4, 1H), 8.85 (d, J = 9.0, 1H), 8.61
(d, J = 7.2, 1H), 8.15 (dd, J =
7.0, 1.5, 1H), 8.08 (d, J = 8.0, 1H), 7.93 (dd, J = 7.6, 1.6, 1H), 7.88–7.63 (m, 7H), 7.61 (d, J = 7.8, 1H), 7.17–7.09 (m, 2H), 7.06 (ddd, J = 7.2, 5.8, 1.5, 1H), 6.94–6.85 (m, 2H), 6.84–6.76
(m, 2H), 6.53 (dd, J = 8.1, 8.1, 1H), 6.46 (dd, J = 7.1, 7.1, 1H), 6.08–6.03 (m, 2H), 2.80 (s, 3H, MeL). 13C NMR (75 MHz, CD2Cl2): δ 182.0, 173.6, 169.1, 163.7, 161.5, 161.3 (all Cq), 153.3 (CH), 152.7, 150.5 (both Cq), 148.7 (CH), 143.3,
142.1 (both Cq), 138.3 (CH), 137.7 (Cq), 135.6,
135.4, 134.0, 131.4, 131.2, 130.8, 129.1, 128.9, 128.0, 127.9, 126.2
(all CH), 125.6 (Cq), 125.3, 124.3, 123.9, 122.6, 122.4,
122.3, 121.8, 121.2, 120.1, 120.0, 114.3 (all CH), 61.9 (Cq), 24.4 (MeL).
Formation of mer-Ir(κ4-cis-C,C′-cis-N,N′ -MeL){κ2-C,N-(C6H3Me-py)} (9b) and
[Ir(κ3-C,N,N′;η2-C,C)-MeHL)(κ2-C,N-C6H3Me-py)]BF4 (10)
These compounds
were obtained following the procedure described for 6b and 8 starting from 7 (275 mg, 0.368 mmol),
2-(p-tolyl)pyridine (63 μL, 0.368 mmol), and
(piperidinomethyl)polystyrene (105 mg, 0.368 mmol). Yield: 9b (red solid), 34 mg (12%); 10 (orange solid), 120 mg
(39%). X-ray quality crystals of 9b were formed from
dichloromethane by evaporation at room temperature. Analytical and
spectroscopic data of 9b: Anal. Calcd for C40H30IrN3: C, 64.50; H, 4.06; N, 5.64. Found:
C, 64.35; H, 3.99; N, 5.42. HRMS (electrospray, m/z): calcd for C40H30IrN3 [M + H]+, 746.2144; found, 746.2168. Td5 = 350 °C.[36]1H NMR (300 MHz, CD2Cl2, 298 K): δ 9.38
(d, J = 5.8, 1H), 8.84 (dd, J =
7.5, 1.5, 1H), 8.08 (m, 2H), 7.98–7.84 (m, 4H), 7.83 (s, 1H),
7.73–7.60 (m, 4H), 7.53 (m, 1H), 7.32 (dd, J = 5.6, 1.4, 1H), 7.13 (ddd, J = 7.3, 5.8, 1.4,
1H), 6.94–6.88 (m, 2H), 6.88–6.75 (m, 3H), 6.70 (dd, J = 7.9, 1.2, 1H), 6.65 (ddd, J = 7.1,
5.6, 1.1, 1H), 6.04 (s, 1H), 2.80 (s, MeL), 1.85
(s, 3H, C6H3Me). 13C NMR (75 MHz, CD2Cl2): δ 178.9, 171.1,
169.1, 168.4, 165.3, 161.8 (all Cq), 152.9 (CH), 150.7
(Cq), 150.2 (CH), 146.6, 142.3, 141.4, 139.2 (all Cq), 138.3, 137.0 (2C) (all CH), 136.4 (Cq), 134.1,
132.0, 130.2 (2C), 129.0, 128.1, 127.7, 125.9, 125.5 (all CH), 125.4
(Cq), 124.6, 123.1, 123.0, 122.9, 122.7, 122.2, 121.88
(2C), 120.0, 119.5, 114.3 (all CH), 60.6 (Cq), 24.6 (MeL), 22.0 (C6H3Me). For analytical and spectroscopic data of 10, see
below.
Preparation of [Ir(κ3-C,N,N′;η2-C,C)-MeHL)(κ2-C,N-C6H3Me-py)]BF4 (10)
Authors: Vadim Adamovich; María Benítez; Pierre-Luc Boudreault; María L Buil; Miguel A Esteruelas; Enrique Oñate; Jui-Yi Tsai Journal: Inorg Chem Date: 2022-04-19 Impact factor: 5.436
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